Control apparatus



Nov. 15, 1938. Q B. MOORE ET AL 2,136,631

CONTROL APPARATUS Filed Oct. 2, 1955 5 Sheets-Sheet l ,f IGA INVENTOR. ANKER E KROGH COLEMAN B. MOORE lBY Q gJ/HTORNEY Nov. 15, 1938. c. B. MooRE ET Al.

CONTROL APPARATUS 5 Sheets-Sheet. 2

Filed Oct. 2, 1935 INVENTOR. ANKER E. KROGH COLEMAN B. MOORE y ATTORNEY Nov.15,1938.

c` B. MOORE ET AL 2,136,631

CONTROL APPARATUS Filed Oct. 2, 1935 5 Sheets-$heet 3 24 fficsfig INVENTOR.

ANKER E. KROGH COLEMAN B. MOORE Nov. 15, 1938. C, B, MOORE ET AL, 2,136,631

CONTROL APPARATUS Filed Oct. 2, 1935 5 Sheets-Sheet 4 INVENTOR. ANKER E. KROGH COLEMAN B. MOORE ATTORNEY NOV. 15, 1938. B MOORE ET ,Mrl 2,136,631

CONTROL APPARATUS Filed Oct. 2, 1935 5 Sheets-Sheet 5 T0 WAT FUMACE FIG. 8. RECTM SECONDARY NAz Dv AA ,8 C RM HHHHHH I v IHIIHIIIH Q CHe k I I II II II I I I I l s PRIMARY I DA CHL\ RDL CH r` A vowzn RC /f 4 Ac conmol. RCL CH fRD 7 a RC' RQH RL RD RH L l C Ro I 'L DC CONTROL IEVRSBLE MDTOR MOTOR "|VEN RHIUSTY R bh Mb Mbh INVENToR.

Lc' ANKER EKROGH COLEMAN B. MOORE A TTORNEY Patented Nov. 15, T938 y vUNlTED STATES PATENT OFFICE CONTROL APPARATUS =Ccleman B. Moore, Carroll Park, and Anker E. Krogh, Erdenheim, Pa., assignorsv to The Brown Instrument Company, Philadelphia, Pa., a corporation of Pennsylvania v Application october 2, 1935, sexismo. 43,150

25 claims. (ci. 23e-ro) This application relates to control apparatus rangement which may be added to the apparatus and more particularly to control apparatus for shown in Fig. 3;

controlling a variable condition,ysuch as pres- Fig. 4 is a sectional side elevation of the opsure, temperature, humidity, flow or the like, poslte side of the instrument side plate shown 5 to maintain a predetermined value of said conin Fig. 3; 5 dition. Fig 5 is another perspective view of a portion More particularly our invention relates to ap of the control apparatus; paratus designed to eiect control actuations in Fig. 6 is a diagrammatic view of the operating response to deviations of a deflecting meter eleparts of Fig. 5;

ment from a predetermined -position and to set Fig. '7 is a wiring diagram showing the circuit l0 into operation in response thereto, agencies tendconnections for use with the control apparatus; ing to return said element to said predetermined Fig. 8 is a circuit diagram of another embodinormal position. ment of our invention, and

Still more particularly our invention is con- Fig. 9 is a circuit diagram of still another emcerned with control instrumentalities operating bodiment of our invention. 15

in response to changes in a variable condition to The recording potentiometer instrument control the latter within close limits, which inshown in perspective in Fig. 1, and significant strumentalities are robust in construction and operative parts of which are illustrated in Fig. 1, adaptable to heavy duty service such as is reincludes a galvanometer, the pointer 2 of which 30 quired in industrial plants, Such for example as deilects in response to a condition of unbalance 20 in steel mills and the like. in the potentiometer measuring circuit which In the Thomas R. Harrison Patent 1,946,280, vmay be any well known form including the reissued February 6, 1934, control instrumentalisistance 2|.which may be adjusted to rebalance ties were disclosed whereby control elements the potentiometer. The instrument also comsuch as mercury switches were actuated to effect prises mechanical relay provisions operated by a 25 the desired Control action in response t0 the constantly rotating driving motor not shown and deviations of a variable condition from normal. controlled by the deillection of the galvanometer We have disclosed herein, however, modifications pointer 2 away from its normal zero position, to in und iInDrOVeI'nentS Over the disclosures 0f Said periodically rebalance the potentiometer circuit patent. and move a pen or other recorder carriage 23 30 Although adaptable to other uSeS, our invenalongfa travelling record strip 26 to record the tion iS 0f Special utility in ccnneetiOn With Dcvarying value of the quantity measured on said tentiometric measuring apparatus comprising a str1p i galvanometer deflecting in accordance With DO- In respect to its recording potentiometer func- 25 tentiometric unbalanciresulting from a change tions the instrument shown in Figs. 1-6 is of the 35 in Value in a ccnditicn measured by Said apparaform disclosed in an application for patent Setus and automatic potentiometer rebalancing rial Ne 546,290, med June 23, '1931, jointly by means serving also to adjust an indicator vor Ernest H. Greuel, Ernest Kessler and Thomas R. recorder member. When so used our invention Harrison, and in respect to the type of control lo includes the control of mercury switches or anmechanism employed herein we make use of cer- 40 alosous control devices jointly in response to the tain instrumentalities disclosed inthe previously deilections of the galvanometer and the deilecmentioned Harrison patent. tions of the indicator or recorder member. The control previsions, which 1n their con- These and Other attendant Objects and adstruction and arrangement, and in their com- '25 vantages will be manifest from the detailedidebmetion with the above-mentioned rebalancing 45 scription following when taken in connection and carriage adjusting and control mechanism, with the accompanying drawings WhereOf constitute the features of the present invention,

Fis. 1 is a perspective view of a portion of the include a control table A and means by which apparatus; f control switches are periodically actuated by said n0 Fig. 2 is another perspective view of the conmechanism, when the recorder carriage 23 is 50 trol apparatus; displaced in one direction or the otherfrom the Fig. 2A isa plan view of the recorder carriage; control table. The control table A lis normally Fig. 3 is a side elevation looking generally stationary but may be manually adjusted along from the right 0f Fig. 1; the path of movement of the carnage 23. The

Fig. 3A is an elevation of an interruptor arposition of the control table along said path cor- 55- responds to, and determines the normal value of the quantity measured, while the position at any instant, of the carriage 28 corresponds to, and constitutes a measure of, the current value of said quantity.

The mechanism of the instrument of Fig. 1 through which the deflection of the galvanometer pointer 2 controls the adjustments of the recorder carriage 23 and the rebalancing of the potentiometer circuit on a variation in the quantity or value measured by the galvanometer comprises a pointer engaging and position gauge element 3. The latter is pivotally supported and in connection with the hereinafter mentioned shaft 6 has a loading tendency, which may well be due partly to spring and partly to gravital action, to turn upward into the position in which one or another of the shoulders S of the member 3 engage the pointer 2. 'I'he element 3 is engaged by, and turns, with the arm 6 of a rock shaft 6. A spring I0 tends to hold a rocker 8 which is journalled on a pivot S, in the position in which the rocker engages an arm 1 secured to the shaft 6 and thereby holds the latter in a position in which the shoulders S are all below the pointer 2.

A cam II which is carried by a shaft I2 constantly rotated by the instrument driving motor through a speed reduction gearing, turns the rocker 8 about its pivot against the action of the spring I0, once during eacii'V revolution. This allows the arm 'l to turn counter-clockwise, as seen in Fig. l, until the corresponding angular movement of the shaft 6 is interrupted by the engagement of one or another of the shoulders 5 of the member 3 with the galvanometer pointer 2. The shoulders 5 are so arranged 'that the turning movement of the shaft 8 and arm 1 thus permitted. will be greater or less according to the deiiective position of the pointer 2 at the time. When the arm 'l thus turns counter-clockwise, a lateral projection 1' of that arm engages and turns a secondary pointer element I4 into a position corresponding to the then deflection of the pointer 2. 'I'he secondary pointer I4 is loosely journalled on the shaft i, and has a gravitational loading tendency to turn in the clockwise direction as seen in Fig. 1, so that the arm I4 normally-bears against the projection 1' of the arm 'I.

At the end of each angular adjustment of the secondary pointer I4 into a position corresponding to thel then deflection of the galvanometer 2, one or another of the three shoulders ISH, ISN and ISL of a locking member I S, engages the bottom wall of a slot I4' in the member I4 and thereby frictionally holds the latter in the position occupied by it when such engagement occurs. When the pointers 2 and I4 occupy their neutral positions, the shoulder ISN of the member I5 comes into locking engagement with the member I4. When the galvanometer pointer 2 has deflected to the right as seen in Fig. 1,as it does when the actual value of the quantity measured is lower than that indicated by the previously made and still existing potentiometer adjustment, the secondary pointer I4 is engaged and locked by the shoulder ISL. When the galvanometer pointer deflects in the opposite direction from its neutral position, as it does when the actual value of the quantity measured is higher than that indicated by the existing potentiometer adjustment, the pointer I4 is engaged and locked by the shoulder ISH of the member I 5. The locking part IS is given a tendency to move into locking engagement with the secondary pointer I4 by the spring I0, but is periodically held out of such engagement by the action on its projection I5 of a projection I 6A carried by a ratchet lever I8 pivoted at IEB.

A spring ISC gives the lever IS a tendency to turn forward in the clockwise direction as seen in Fig. l, but throughout the major portion of each rotation of the shaft I2 the lever I6 is held in a retracted position by a cam I1 carried by said shaft and engaged by the cam follower roll ISD carried by the lever I6. The ratchet lever IS is operatively connected to two pawls ISE and IBF cooperating with a toothed wheel I8. Each of said pawls have a gravital tendency to occupy a position in which it does not engage the teeth of the wheel I8, but one or the other of the pawls is brought into engagement with the teeth of the wheel on each forward or clockwise movement of the lever I6, if the locking part IS is then at one side or the other of the intermediate or neutral position which it occupies when the galvanometer pointer 2 is in its neutral position.

The position assumed by the part I5 when in locking engagement with the secondary pointer I4, controls the action of the pawls ISE and IBF by virtue of the fact that a collar or hub portion I5"' of the part I5 carries a spring pawl engaging arm I5". The movement of the locking part IS into the position in which its shoulder ISH engages the secondary pointer I4 causes the arm I5" to move the pawl ISE into operation engagement with the teeth of the ratchet wheel I8, and the clockwise or forward movement of the ratchet lever I8 then gives a clockwise adjustment to the ratchet wheel. Conversely, when the part IS moves into the position in which its shoulder ISL engages the secondary pointer I4, the arm IS" shifts the pawl ISF into operative engagement with the wheel I3, and the latter is then adjusted in the counter-clockwise direction.

The extent of the adjustment then given the wheel I8 is made dependent upon the position of the secondary pointer I4, as said position determines which of the various shoulders of an arm ISG carried by the lever I6 shall then engage a projecting portion I4" of the secondary pointer I4 and thereby arrest the forward movement of the ratchet lever IS. In the neutral position of the galvanometer pointer and secondary pointer I4, the projection I4" of the latter engages the central shoulder ISG' of the arm ISG and the lever I8 is then held against any operative movement in the clockwise direction. When the secondary pointer position is more or less to one side or the other of its neutral position, the portion I4" engages an upper or lower shoulder ISG2 or ISG3 more or less ditsant from the central shoulder ISG1 and the lever I6 is then Permitted more or less forward movement.

The rotation of the Wheel I8 in one direction or the other effects corresponding potentiometer rebalancing adjustments and position adjustments of the recorder carrier 28. The rebalancing adjustments are effected by means of a rheostat shaft I8 which is geared to the shaft I 8 on which the wheel I8 is secured. The rotation of the shaft I9 moves a -bridging contact 28 along the convolutions 2| of a potentiometer resistance helically disposed about the axis of the shaft I9, and thereby varies the amount of said resistance in the potentiometer circuit. The resistance adjustments made in response to a deflection of the galvanometer pointer in one direction away from its neutral position rebalanoes, or tends to rebalance, the potentiometer circuit and thereby returns, or tends to return, the galvanometer pointer to its neutral position.

The rotation of the wheel I8 adjusts the recorder carrier 23 by virtue of the fact that the teeth of the wheel I8 are in mesh with the teeth of a gear carried by a carriage adjusting shaft 22 which is formed with a thread groove 22' of coarse pitch which receives a cam or mutilated `screw thread rib secured to the carriage 23, so

that the latter is moved longitudinally of the shaft 22 as the latter is rotated.

The marker carriage 23 comprises a frame portion formed of a single piece of sheet metal cut and bent to form a at underbody portion with i uprising projections. Those projections include two apertured ears 23a at the rear corners of said body portion transverse to and through which the shaft 22 extends; two projections 23h, one at each front corner of said body portion which bear against the inner edge and upper side of the lower flange of a channel bar or rail 24 forming part of the instrument framework, and three intermediate projections 23c which extend in vertical planes transverse to, and are arranged in a row parallel to, the shaft 22 and rail 24. In addition the body portion of the carriage frame is provided with a forwardly extending tongue passing beneath the rail 24 and terminating in an uprising pointer or index 23d adapted to cooperate with a scale marked on the front face of the rail 24 to indicate the position of the pen carriage, and the value of the quantity measured and recorded by the instrument. Projections 23c support a shaft 23e carrying a part 23F, on which is mounted the recording pen 25 which traces a record of the' quantity measured on a record sheet 26. The instrument includes means shown in the drawings for adjusting the part 23F relative to the carriage 23 in the longitudinal direction of the shaft 23e to compensate for the expansion and contraction of the record sheet 26 caused by changes in the atmospheric humidity. Such compensating provisions do not vary. the position of the recorder carriage 23 though they vary the position of the pen supported by the carriage, and form no part of the present invention, and therefore need not be described or further referred to herein.

The record sheet 26 passes over and is given feeding or advancing movements by a record feed roll 21. The latter is intermittently rotated by means of a worm and screw connection between the shaft of the roll 21 and a transverse shaft 28. Shaft 28 is intermittently actuated by means of a ratchet and lever device 30 which is engaged and oscillated by the arm 8 of the rocker 8 on each oscillation of the latter.

The control table A of the instrument shown in Figs. 1 and 2 comprises a sheet metal frame having ear portions A apertured for the passage of a shaft B mounted in the instrument framework alongside the shaft 22 and having bearing parts A2 which engage and slide along the upper ange of the rail 24. To facilitate the adjustment of the control table A along the path of travel of the pen carriage 23, the shaft B is shown as formed with a thread groove B1 receiving a cam or mutilated thread rib part A3 secured to the ment of the table and the corresponding normal vvalue of the quantity measured.

A member a is hinged at one edge to the frame of the control table A by a pivot or pintel shaft a extending parallel to the shaft B. The member a is formed with guiding provisions including a part a2, for a bar-like part C which extends parallel to the shaft B and is rigidly secured at its ends to arm C1 at opposite ends of the instrument which are pivotally connected at C3 to the instrument framework so that the yoke like structure formed by the bar C and arms C1 may turn with yrespect to the instrument framework about an parts a and C are positively held in their upper' most positions by the action of a link O5. As will hereinafter appear, link O5'is given rising movements 'during which the edge O6 of link O5 will engage and '1 raise `the projection C4 of arm C1 carrying-.the latter to its highest or clearance position. The extent to which the parts a and C arepermitted to swing downwardly from their uppermost positions during each period when the action offthe cam Il renders the link O5 temporarily inoperative, depends upon the then relative positions of the table A and the recorder carriage 23. `v When the value of the quantity measured is so Ar,low `that the carriage 23 is entirely at the low side (left-hand side as seen in Fig. 1) of L the control table A, the carriage 23 does not interfere with the movement of the parts a and C into their lowermost positions.

When the current value of the quantity measured is suitably close to the normal value of that quantity, the control table and marker carriage 23 are in such relative positions that downward movement of the hinged part a is prevented or restricted by the engagement of a portion of that part with the marker carriage 23. For the purp pose of such engagement the part a, as shown in Figs. 2 and 4. has a carriage engaging portion a5 detachably secured to it. The" part a5 is in the form of a plate with a downwardly projecting body portion terminating in a lower horizontal edge aH, and a series of steps aH, aN, aL and aL1 vertically removed from edge aH1 but parallel thereto and having at its upper edge a lateral flange portion bearing against the underside of the part a at the rear edge of the latter and detachably secured thereto by cla-mping screws al. The bodies of said screws pass through slots in the part a which are open at the rear edge of the latter.

The lower edge 11H1 of the projection a5 is so disposed that it may engage and rest upon the shoulder 23C formed by the upper edge of the projection 23e at the high side of the recorder carriage 23 (the right-hand side as seen in Fig. l), when the position of said carriage is such as to hold the shoulder 23C beneath said edge aHl.

In the condition just described the control table part a cannot move downward below the position in which edge aH1 contacts shoulder 23C which is the upper operating position of the part a.

lThe movements or' the part a above this position are inoperative movements insofar as the actua- 'tion oi the control devices is concerned. The uppermost position of the a above this position may be called a clearance position since in that position, part a cannot interfere in any way with movements of the carriage 23, all of which are given'the latter while the part a is held in said clearance position.

When an increase in the value of the quantity measured results in a movement of the recorder carriage 23 to the high side oi `the control table A, that movement causes the part a to be positively secured against down movement from its uppermost operative position by adjusting a latch member D, into its latching position. l'i'he latch D is pivotally mounted on a stud A4 depending from the underside of the plate-like body of the table In the latching position of the member D, a nger-like portion of 'the member extends beneath a portion a8 of the part a which is some distance to the rear of the hingeshaft a".

Latch member D is automatically moved into and out of its latching position, as the carriage 23 moves to and returns from the high side of the control table A, by means which include a vertically disposed shoulder or edge 23B of the projection 23h at the lov.7 side front corner of the recorder carriage frame, a member d pvotally mounted on a stud A depending from the underside of the control table frame alongside the stud A4, and a spring Dd connecting the members D and d. The spring Dd tends to move the member D in the counter-clockwise direction as seen in Fig. 2 and to move the member d in the opposite direction about their respective pivotal V supports A4 and A5; such turning movements of the members D and d are prevented by the engagement of the nger portion d of the part d with the shoulder D of the member D, when the latter is in its latching position as shown in Fig. 2. In the non-latching position of the member D, the nger d engages a shoulder D2 of the part D. The members D and d are moved from the latched position shown in Fig. 2 into the unlatched position and back again into the position shown in Fig. 2 by the engagement of the recorder carriage shoulder 23B with the cam shaped front edges D5 and d5 of the members D and d, respectively. The edges D5 and d5 are so respectively shaped and disposed that as the carriage moves to the high side. of the control table, the shoulder 23B acts on the edge of d5 to turn the member d counterclockwise, as seen in Fig. 2 so that the spring Dd malthen move the member D into its latching position in`which its shoulders D' engages the finger d'. When the carriage 23 subsequently moves back from its high position, the shoulder 23B engages edge Ds of the member D and moves the latter into its non-latching position while permitting the spring Dd to move the member d into the position in which its nger d engages the shoulder D of the member D, and holds the latter in its non-latching position.

When the value of the measured condition is at normal, which will occur when the index 23d of the carriage 23 is adjacent the index As of the table A, the projection 23C of the carriage 23 will be so disposed with relation to the table A that upon a downward movement of the part a, the step aN of the part a5 will engage said projection. A slight increase in the value of the quantity measured will result in a deflection of the carriage 23 to the right as seen in Fig. 2

.- in which position a downward movement of the 'tity to produce a resultant control action.

previously described, the mechanical relay provi-y part a will result in engagement of the step aH with projection 23C, a further deilection of carriage 23 to the right or the high side will cause engagement of the step aHl with projection 23C when part a is depressed as 4previously described. Gn a slight decrease in the value of the quantity measured, from the position in which the projection 223C is disposed beneath the step aN, the projection 23C will be in a position in which it is adapted to be contacted by the step aL upon a downward movement of the part a, and upon a further decrease in the quantity measured resulting in further deflection ofthe carriage 23 to the left as seen in Fig. 2 Jthe projection 23C Vwill be in a position in which it is adapted to be engaged by the step aLl. Further deflection of the carriage 23 to the low or left hand side will carry the projection 23C beyond the province of the part a and in this position the part a will not be intercepted by the projection 23C but the part a will be permitted its full downward motion as limited by engagement of the projection C4 of the member C1 with the top edge of the instrument side plate. The lowest limit to which table part a is permitted to fall when projection C4 engages the side plate is also the limit to which part a falls when step GL1 engages projection 23C.

The above described cooperation of the control table A and the pen carriage 23 may be utilized to directly effect control action as desired but it is the object of the present invention to combine with the action resulting from the cooperation of the control table and the pen carriage, further control functions contributing to a iiner degree of control than would be possible with the former alone. The action due to the cooperation of table A and carriage 23 just described might be termed a magnitude function since it is an action in response to the total deviation of the quantity from a predetermined value and I de sire to combine therewith a control action which is a function of the rate of change of said quansion of Fig. 1 rebalances the potentiometric circuit, to the unbalance of which the galvanometer pointer 2 is responsive, and accordingly the rebalancing operations restore or tend to restore the galvanometer pointer 2 to its neutral position or null point. The rebalancing operations occur at regular intervals so that the periodic restoral tion to and deflection from neutral of the galvanometer pointer 2 renders the extent of deflection of the latter when clamped at regular intervals, a measure of the rate of change of said quantity.

The means by which the existing deilection of the galvanometer pointer 2' comprising the rate of change component, is measured and combined with the deviation component resulting from the cooperation of the control table A and the car-v rage 23 includes stop and guiding members for a link O5 shown in Fig. 4 and a iloating member E connected to said link. 'Ihe member E is pivotally connected at EF to the part F of a. compound lever comprising parts F and FA each -pivoted to the instrument framework at Fl and normally held against relative'- Amovements by' s. spring FB. The latter tends to hold the part F in engagement with a projection FAI of the part FA, but serves as a safety device which may yield to prevent injury of the part in case the switch parts actuated by .the member should jam. A spring FA3 extends between 'the upper end of lever FA and the instrument framework and tends to hold the part F, FA and Ein the position shown in dotted lines in Fig. 4. The lever part FA is moved from the dotted line position into the full line position in Fig. 4 once during each rotation of the shaft I2 carrying the cam II which eiects such movement by its engagement with a cam roller FA2 carried by the lever part When the parts are in the position shown in dotted lines in Fig. 4, the lower cam edge E1 of the member. E rests upon a roller support e mounted on the instrument framework, and the position of the member E is then such that the link O5 is raised to an initial or clearance position from which it is subsequently permitted to descend. When the lever part F is turned in the clockwise direction from its Fig. 4 dotted position the weight of link O5 and member E causes the latter to rotate about pivot EF, moving link O5 downward until intercepted by engagement of its upper end with the cooperating control mechanism.

The control mechanism comprising the leveling and guiding means for the link O5 includes an extension |50 of the member I5, a lever Q and extension S of arm C1. The lever Q, which is the element by which the rate of change component is introduced into the collective control action, is journalled to the instrument framework at C3 and carries a pin Q'O adapted to be engaged by slot O7 of link O5 whereby the up and down movements of the latter are guided over one or another path depending upon the position of pin QO. Pin QO extends through the aperture IOI in the instrument side plate. Lever Q has a gravitational tendency to fall downward into a position in which the pin Q1 thereof engages the upper edge of extension |50 of member I5. As explained in connection with Fig. 1 the member I5 once in each cycle of operation of the insirument, assumes a position depending upon the then position of the galvanometer with respect to its norma'l position. The member I5 will be in a neutral position wherein step I5N engages the secondary pointer I4, when permitted to do so, if the galvanometer is then at its neutral position indicating a stationary condition of the measured quantity. A trend of themeasured quantity above or below its then value will result in an engagement of step ISH or I5L of the member i5 with the pointer I4 thereby positioning the extension |50 of the member I5 to one or the other side of said neutral position. Each of the positions in which the lever Q is held by extension |50 defines a position for the pin QO of the member Q thereby forming three generally vertical paths for the link O5.

'I'he downward movement of the link O5 over one or another of its three paths as determined by the pin Q will be terminated by engagement of the projection OS of the link O with one of a series of steps S111, SL, SN, SH, or SHl, of the extension S of the arm C1. The extensionr S will be angularly positioned about the center C3 upon each downward movement of the part a, into one of iive positions depending upon which of the steps aLl, aL, aN, aH, or aH1, of the part a is intercepted by the projection 23C of the carriage 23. The particular one of the steps of the extension S which is engaged by the projection OS of the link O5 will therefore be determined jointly by the path over which the link O5 travels in the downward movement of the latter as determined by the then position of the pin QO and upon the angular position of the extension S about the pivot C3. When the step I5N of the member I5 engages the secondary pointer I4, as it will when the trend of the condition is stationary, and the step aN- of the part a is then in engagement with the part `23C of the carriage 23, the step SN of the extension S will be engagedby the projection OS of the link O5 in the downward movement of the latter.

As previously described, the downward movement of the link O5 is caused by the weight of the parts as the member E moves to the left in Fig. 4 and the cam edge E1 is formed with a sharp initial drop so that link O5 rapidly moves into contact with extension S upon the beginning of the movement to the left of member E. Further counterclockwise movement of the member E as seen in Fig. 4 with the projection OS of the link O5 in engagement with the step SN of the exten- 1 sion S will result in deflection of the member E over the middle path indicated diagrammatically as N in Fig. 4, of a plurality of paths of which in the present embodiment there are live. So long as the trend of the condition is stationary the pin QO will be in the position just described at the commencement of each downward movement of the link O5 and the particular step of extension S which is then engaged by the projection OS will then be determined solely by the position of the pen carriage 23 with respect to the control table A and thereby in accordance with the value of the measured condition with respect to the normal value of the latter. If the downward movement of the part a results in engagement of its step aL with the projection 23C the step SL of extension S will be positioned in the path of the projection OS in the down travel of the link O5. If in the downward travel of the part a, the step aLl of the latter is engaged by the projection 23C the step SL1 of the extension S will be then positioned in the path of the projection OS. Upon a rise in the magnitude of the measured condition whereby the down movement of the' part a results in engagement of the step aH with the projection 23C the step SH of the extension S will be positioned in the path of the projection OS and upon a further deection of the carriage 23 to the high side whereby the step aI-I1 of the part ct contacts the projection 23C, or part a is latched up, the step SH1 of the extension S will be positioned in the path of the projection OS of the link O5. As will be clear from Fig. 4, movement of member E to the left with link O5 in engagement with steps SH, SHI, SL or SLl, of

member S, will result in member E deflecting over paths H, H1, L and L1 respectively of Fig. 4.

If the trend of the condition ls rising or falling the step I5H or the step I5L of the member I5 will engage the secondary pointer I4 upon the counterclockwise movement of the member I5 as seen in Fig. 4 and the resultant change in the position of the pin Q0 will determine a path for the link O5 which, for a given position of extension S, will result in engagement of its projection OS with a. different step of the extension S than would be engaged when the member I5 is in its neutral position.

With the step ISH of the member I5 in engagement withthe secondary pointer I4 the pin Q0 will be turned to a position clockwise of the neutral position illustrated in Fig. 4 thereby moving the projection OS transversely ofthe path of the link O5 so that projection OS is moved into alignment with a step of the extension S which is one step further removed tothe high side than is the case when the pin Q is in its neutral position. Thus with the part a of the table A in such position that its step uit' engages the projection 23C, and the member l5 in such position that its step HH is in engagement with the secondary pointer il the down movement oi the link O' will result in engagement of the projection OS with the step IEH of extension S. With the step ibiin engagement with the secondary pointer it but the step aH of the part a in engagement with the projection 23C the down movement ci the link O5 will result in engagement oi the projection OS with thev step SHI of the extension Si. With the step 95H in engagement with the secondary pointer it and the step ai? oi the part o in engagement with the proection the subsequent downward movement oi the llni: C5 will again 4result in engagement of the projection CS with the step SHI of extension S. L'n the last mentioned conditlon'of the parts it will be understood that we might extend the operation providing an additional step on extension S and might modify the part a and extension S to extend the operation indennitely, but we prefer to make the actuation resulting from the engagement oi projection 0S with the step SHlthe maximum actuation in that d rection.

Similarly when step @5L of the member ib is in engagement with the secondary pointer il,

pin will be moved to a position counterclcclb wise of the neutral positionA oi" e and wit step elfi of part d in engagement with the projection the step @L ci extension S will be the path of the projection @Es o link O5. With step ibi; in engagement with the secondary pointer the engagement ci step aL ci the part a with projection 23C will result in engagement of the projection OS of link @E with the step Sie ci the extension S upon downward movement of With step HSL in engagementv with pointer ifi and step aLl in engagement with projection the projection CES 'siii again engage step SLI of extension B, the latter being the lowest step provided in this ernoodim-ent.A

Each of the positions ci the link O5 in engagement with a step aLI, aL, aN, cH or aHI of the extension S, above referred to, will determine a different path for the member E in its movement to the left in Fig. e which will correspond respectively to the paths LI, L, N, H and HI diagrammatically shown in Fig. 4.

The paths indicated in Fig. 4 which are selectively taken by the member E in accordance with the foregoing may be conveniently tabulated as follows in which aHI, aH, aN, aL, and aLI indicates the step of part a then in contact with projectlon 23C, 15H, 15N and 15L indicates the step of member l5 then in contact with pointer I4.

The movement of the member E to the left in Fig. 4 will thus be terminated with the latter 'in one of the five positions and the member E may be utilized to actuate any of various known control clcvicesjnA deecting over the selectedone of its five control paths. We preferably switches indicated at A0, Bu and C0.

'I'he means for actuating the switches A0, B and C0 through member E may, as shown in Figs. i and 5 and 6, include three switch actuating members EA, EB and EC, all effectively integral with the member E, and adapted to cooperate with three arms HA, HB and HC, the latter of which are journalled upon the shaft I. Arms HA, HB and HC are attached to yoke members hA, hB and hC respectively, to the latter of which are securedy the downwardly extending switch holding brackets hAI, hBI and hCI carrying switches A, B0 and Ca respectively. Switches A, B0 and C", as shown, are mercury switches of the well known type comprising an envelope with a quantity of mercury therein adapted to shift within the envelope, and bridge metal contacts disposed within the latter. one direction, to bridge two contacts disposed in one end of the envelope, when tilted in the opposite direction, to bridge two contacts disposed in the opposite end of the envelope land when in a position intermediate the two positions just mentioned is adapted to bridge one oi each of the two end pairs of contacts and a iifth contact disposed in the center of the envelope. Switches Bo and C0 are adapted to independently occupy only two positions corresponding to the two tilted positions of switch A0 and have two pairs of end contacts as in switch H0 but no ilith or center contacts since switches B0 and C0 never occupy an intermediate position.

Arms HA, HB and HC, adapted to oscillate about shaft l' are provided with projections HAI- i-iAI, HB1-HB2, and HCI-HG2, respectively which are formed in the planeoi movement of members EA, EB and EC. Members EA, EB and EC are provided with lingers adapted to selectively engage the projections of arms HA, HB and HC as member E is deected over one or another of its five paths. Member EC is provided with a finger ECl adapted when member E travels over path HI, H, N or L, to engage projection HCI oi arm HC and turn the latter counter-clockwise as seen in Figs. 5 and 6 to thereby tilt switch C to what may be termed a forward position. Member EC is provided with another nger ECI which is adapted, when the member E travels over path LI to engage projection HC2 ofl arm HC turning the latter clockwise to thereby tilt switch C into 'a back position. Member EB is provided with a. finger EBI adapted to engage projection H'BI of arm HB and turn the latter counter-clockwise when member E deflects over path H, N, L or Ll thereby tilting switch B to its forward position. .Member EB is provided with another ilnger EB2 adapted to engage projection HBz of arm HB when member E is deected over path HI, to turn arm HB clockwise thereby tilting switch B0 to its back position. Member EA is provided with two fingers EAI and EA2 each of whch is provided with a high portion EAH or EAL and a low portion EAN. When member E is deflected over path H or HI the edge EAH is adapted to engage projection HAI of arm 'HA turning the latter counterclockwise in Fig. 5 to tilt switch Au to its forward position. When member E is detlected over path L or LI the edge EAL is adapted to engage projection HA? of arm HA to turn the latter clockwise thereby tilting switch Ao to its back position. When member E deilects over its actuate three intermediate path the edge EAN of each finger EAI and EA2 engages a projection HAI and HA| whereby .arm EA is moved to a position intermeswitch A0 is adapted when tilted in diate its two extreme positions and switch A0 is lodged in its mid or neutral position. A table of the foregoing actions may be conveniently made as follows in which F, Bo and N denote the forward, backward and neutral positions of switches A0, B0 and C0.

Switches A0, Bu and Co as shown in Fig. 7, are adapted to control an electrical motor M which may be arranged to control a corrective agent for the condition to which the galvanometer 2 is responsive. If the galvanometer 2 is responsive to temperature, for example, the fuel supply to a furnace burner or the like, for governing said temperature may be supplied through the pipe N3 having inserted therein the control valve N1. Control valve N1 may be adjusted by means of the lever N2 under control of the lever MN, the latter of which is positioned by the motor M. Motor M is of the reversible type having fields Mh and M1 adapted, when individually energized, to turn a worm M1 in a directionto close or open, respectively, the valve N. As diagrammatically shown, worm M1 is connected by means of worm wheel M11 and link M3 to the lever MSN.

Another link M4 attached to worm wheel M2 is adapted to actuate limit switch mechanism MS comprising a block MS1, pivoted at MS2 and cooperating switch blades operated by the block. Rotation of wheel M2 and consequent movement of link M4 will result in proportional rotation of block MS1 so that the position of the latter is proportional at all times to the valve position. The upper right and lower left cam edges of block MS1 are adapted to engage respectively the switch blades MSL and MSh1 pivoted at M83 and M84, to separate the switch blades in succession from the stationary contacts Mh1 and Mhz, the

latter of which are connected by conductor Mh3 to field Mh of motor M. Upon energization of field Mh through contact MS1, block MS1 will be rotated in the clockwise direction until switch blade MSh is parted from contact MS1 by the contact of block MS1. The rotation of block MS1 sufficient to open switch MSh is insuiicient to open switch MSh1, but upon energization of field Mh through contact Mk2 the block MS1 will be rotated further in the clockwise direction until switch blade MSh1 is contacted and opened by the lower left cam edge of block MS1. Similarly, the eld Ml is connected to stationary contacts MU and M12, through conductor M13, which con-A tacts cooperate with switch blades MSI and MSZ1 pivoted at MS5 and MSB, the switch blades being adapted to be successively contacted by the upper left and lower right cam edges respectively of the block MS1 as the latter `is rotated counterl wise or counterclockwise an amount suiiicient to open respectively, contact MSh or MSI. Switch member MSA1 is pivoted at MS8 and is also connected to block MS1 by a pin and slot so that it is rotated in the opposite direction upon rotation of block MS1. Contact Mh4 and M24 carried by member MSA1 are adapted to engage contacts Mk2 and Ml2 when block MS1 is rotated sunlciently to open respectively, the switches MSl1 and MSh1.

When the value of the condition is appreciably low and the trend is falling or is stationary, switches A0, Bo and C0 will occupy the positions shown in Fig. 7 in which switches A0 and Co are in the backward positions and switch Bu is in its forward position. 'I'his relation of the parts will exist in a temperature control system, for example, when the furnace or the like is being ,started up while cold. A circuit will be thus completed from line LC to switch C0, through the latter to conductor Cl and switch blade M511, contact M12, conductor M13 to field MZ, armature Mu), to the opposite line conductor LC1. Motor M will thereby be rotated in a direction to open valve N1 which movement will be terminated by the engagement of cam MS1 with switch blade MSZ1, the prior engagement of switch blade MSZ having no effect during this operation. Motor M is thus rotated to the limit of its movement in the opening direction. At the end of the movement of block MS1, the members MSA and Mh1 will be brought into engagement with contacts Mhl and M712 respectively.

On a rise in the trend of the condition resulting from the relatively large correction by valve N1, the member E will be deflected over its path L as a 'result of the engagement of step l5H of member l5 with pointer I4, the part a still being appreciably below normal. Switch C0 will thus be actuated to its forward position and switches Ao and B0 would be actuated to their backward and forward positions respectively if they were not already in those positions. A circuit will be thereby completed from line LC to switch C", conductor CB, switch B0, conductor BD, switch D0, conductor DA, switch A0, conductor AL and switch blade MSh4 which is then in engagement with contact Mhz, through the latter and conductor Mh3 to eld Mh of motor M. As hereinafter explained, the above mentioned switch D0 is closed except during a brief portion of each operating cycle, in which, for safety reasons, it is moved into open position shown in Fig. 7. Motor M will thus be rotated to move valve N1 in the closing direction which will be terminated by the separation of switch blade Mh1 and contact Mh2. Although the movement of valve N1 just described will reduce the fuel supply, the adjustment of the parts is such that the fuel supply will still be greater than the amount required to maintain the condition at normal.

If the condition trend is then checked and is4 stationary but with the value of the condition somewhat below normal, the member E will be again deflected over its path L and would again complete the circuit just traced if the contact Mh2 and switch blade Mh4 were not then separated, thus maintaining a valve opening somewhat greater than normal.

When the condition risesas a result of the still larger than normal valve opening but with the condition slightly below its normal value, the member E will be deflected over its neutral path N'- whereby switch A0 will be adjusted to is mid position and each of switches Bo and C0 would be Led adjusted to its forward position if it were not already in that position. A circuit will thus be closed over the conductor LC to the switch C11, conductor CB, switch B0, conductor BD, switch D0, conductor DA, switch A0, conductor AN to switch blade MSA which is then in engagement with the contact M111, through the latter, through conductor MILS to eld Mh of the motor M, armature M031 to the line LC1. Motor M will be energized to move the valve N1 in the closing direction, which movement will be terminated by the disengagement of switch blade MSA and the contact Mk1. The position in which the valve N1 is disposed at the termination of the i5 foregoing operation is calculated to be suiicient to maintain the condition at its normal value.

When the value of the condition has increased to its normal value and at that time the trend is stationary, the member E will again be deiiected over its neutral path N which would resuit in the completion of the same circuit as just described, if the limit switch were not then open so that the valve N1 will be maintained in its normal position.

Upon a rising trend of the condition, with 'the value at normal, the member E will be deflected over its path H whereby switch A will be urged to its forward positionv and each of switches B0 and C11 would be actuated to its forward position if they were not already in that position. A cirn cuit will thus be completed over conductor LC, switch CG, conductor CB, switch B0, conductor BD, switch D11, conductor DA, switch A0, conductor switch blade MSL, contact Mk1, conductor M to iield of motor M thereby energizing the latter to move valve N1 in the closing direction. The closing movement of valve N1 will continue until terminated by the disengagement of member iz/iSz and contact Mk1. The member MSA during this movement will be brought into engagement with contact lsf.

if the last mentioned movement of valve N1 is sufficient to check the trend oi the condition and the trend therefore becomes stationary, the part c, representative of the value of the condition, will be in a position slightly to the high side and member E will again be deflected over its path I- by reason of the slightly high value of the condition and the stationary trend. Motor M will not therefore be further energized as a result of this action but will maintain the valve N1 in the position in which it supplies somewhat more than the normal fuel supply.

If the trend of the condition continues to rise, the combination of the high and rising condition will result in deflection of member E over its path H1 thereby turning switch B0 to its backward position but maintaining the forward position of switch A0 and switch C0. A circuit will be thus completed sfrom conductor LC to switch C, conductor CB to swich B0, over conductor Hh to member MSh1, which is then closed because the preceding motion of valve N1, suficient to open member MSh, is insuflicient to open member MSh1; to contact Mhz, conductor Mh, eld Mh, armature Ma1 and the opposite side of the line LC1. Motor M will thus'be rotated in a direction to further close valve N1 which movement is terminated by the engagement of block MS1 with member MSh1. During this movement, contact M14 will be brought into engagement with contact M12.

When the rising trend of the condition is checked and is stationary but with the value of the condition still appreciably high, it is desirable armature Ma1 and line LC1.

to continue the appreciably decreased valve opening and with this condition, member E will again be deiiected over its path H1 resulting in no change in the position of valve N1.

When the oonditioncommences to fall but is still appreciably'high, the member E will be deilected over its path H in which each of the switches will be in its forward position. A circuit will therefore be completed from conductor LC, switch C11, conductor CB, switch B0, conductor BD, switch D0, conductor DA, switch A0, conductor Ah to member MZ", contact M12, conductor M13, eld Ml, armature Ma1 and line LC1. Motor M will thereby be rotated to increase the opening of valve N1 which movement will be terminated when member M14 is separated from contact Ml2 under the action of block MS1. The

position of valve N1 when member M14 is separated from contact M12 in its opening movement is the same as the position of the valve when member MSh is separated from contact M111 in the closing movement previously described. The circuit previously traced, resulting from deflection of member E over its path H, differs from the last mentioned circuit inthat in the former circuit the held Mh or motor M was energized because the valve N1 then occupied a position which required a closing operation to obtain the desired opening while in the latter, theiield MZ was energized because an opening valve movement was required to obtain the proper position.

If the trend of the condition is thus checked and is stationary but the value ori the condition is still slightly high, member E will be again deflected over its path H, completing a circuit as in the last mentioned condition whereby valve N1 will be in o. position somewhat less open than at its normal position.

When the condition, as a result of the decreased valve opening, falls, with the condition only slightly above its normal value, the member E will be deflected over its mid or neutral path N in which switch 1.11 is actuated to its mid position and each ci switches B0 and C11 is maintained in its forward position. With this condition a circuitior motor M wili be completed from line LC to switch C0, conductor lCB, switch B0, conductor BD, switch D0, conductor DA, to the mid contact of switch A0, conductor AN to member MSA, contact M11, conductor M13, eld M1 of motor M,

The latter movement will be terminated when member MSA is separated from contact M11 by block MS1 which will leave valve N1 in its normal position corresponding to the position which it occupies as a. result of a low and rising condition as previously described. The circuit Just described resulting from deflection oi' member -E over path N due to a high and falling condition diiers from the circuit previously traced resulting from deilection of member E over path N due to a low and rising condition in that in the previously traced circuit, the field Ml had been energized and energization of field Mh was necessary to return the valve N1 to its normal position while, in the condition just described, the eld Mh had been energized and energization of field Ml was necessary to return the valve N1 to its normal position.

As the value of the condition decreases to its normal value and at that time the trend is stationary, member E will be again deflected over its neutral path as previously described whereby valve N1 is maintained in its neutral position.

If a falling trend of the condition occurs while the value o1' the condition is normal, the member 7s E will be deflected over its path L in which switch A0 will be moved to its backward position and each of switches Bo and C0 will be maintained in its forward position. A circuit will thus be completed from line LC to switch C0, conductor CB, switch B0, conductor BD, switch D0, conductor DA, switch A0 and conductor Al to member MSl, contact Ml, conductor M11, eld Ml, armature Ma1 to line LC1. Motor M will thereby rotate valve N1 in the opening direction until the operation is terminated by engagement of block MS1 with member MSI. This position of valve N1 corresponds to the previously described position of that valve occurring upon an appreciably low but rising condition. The previously described circuit resulting in this position of the valve N1, differs from the circuit just described in that in the former it was necessary to energize the field Mh in order to give the 'valve N1 a closing movement from its then wider lopen position asrthe furnace was heating up, while in the latter circuit it was necessary to energize the fleld M to give the valveN1 an opening movement from its then normal open position.

If the falling trend of the condition is checked and is then stationary but the condition is slightly low, the member E will again be deflected over its path ,L resulting in again completing the circuit just described and the valve N1 will be maintained in a position opened somewhat more than the normal amount.

A further falling trend of the condition with the value of the condition slightly below normal, will result in deflection of the member E over its path.L1 and a. consequent movement of the switch Ao to its backward position and maintenance oi` the switches A0 and B` in their backward and forward positions respectively, as shown in Fig. 7. A circuit for the motor M will thus be completed which is identical to the circuit first described in which the motor M is energized to move the valve N1 toits max um open position which is terminated by the engagement of block MS1 with the contact MSll.

Although the various circuits for the motor M were described in sequence as they would occur with the stated conditions, it will be understood without specific reference thereto, that the circuits may be completed in any sequence as the various conditions dictate. As an example, if the conditions were such that the member E were deflected over its path H1 which would occur when the condition were high, and rising, the motor M would be energized to rotate the valve N1 to its maximum position in the closed direction. If the trend of the cohdition should sud- A denly reverse and fall, member E would be deilected over path N and the motor M would be operated in a direction and by an amount to operate valve N1 directly to its normal position N, without stopping at its intermediate position H.

'I'he switch D, included in certain of the above traced circuits, is closed throughout the major portion of each cycle of the control mechanism by means of cam I2A1, fixed to shaft IZA. Shaft 12A as seen in Fig. 3 is geared to shaft I2 with an even gear ratio so as to rotate cam I2A1 once during each rotation of shaft I2 and thereby once in each control cycle. Switch D0 is carried by bracket Dl pivoted at D3 and provided with rollerv D2, the latter of which engages the edge of cam I2A1 whereby switch D is tilted clockwise to its off position, for a short period, once in each rotation of cam I2A1. The portion of the cycle during which switch D is permitted to turn to its oii position is the portion of the cycle when member E is being moved to the left in Fig. 4 in its switch actuating movement so that no erroneous circuit connections can be made during the movement of switch A0, B0 or C0 to a new position.

Although we have illustrated apparatus for producing a combinative control action resulting from two components, We may readily convert the apparatus so that it produces a control in accordance with only one component. This end may be attained by removing pin Q1 from its location on lever Q shown in Fig. 3 and screwing the pin in an alternate threaded hole QA1 on member Q. Hole QA1, as will be clear from Fig. 3, is so disposed that when pin Q1 is inserted therein, the latter will be adapted to engage the top edge of the instrument side plate upon clockwise movement of member Q into its Fig 3 position. The angular position in which lever Q is held when pin Q1 is thus engaged corresponds to the mid or neutral position of its three operative positions. It will be clear therefore that not only is the member |50 rendered inoperative by removal of pin Q1 from its Fig. 3 position but the proper functioning of the magniture com- ,ponent is insured by placing pin Q1 inhole QA1 to predetermine a neutral position of member Q in each control operation.l

Similarly, the magnitudev component may be readily eliminated and the instrument made solely responsive to the existing' position of the member `|50 by moving the pin C4 from the position shown in Fig. 3 to the hole CA4 provided in the member C1. When so moved the pin C4 is adapted to contact the top edge of the instrument side plate when the member C1 is moved clockwise into'the position shown in Fig. 3, in which position the member S is held in its mid or neutral position. In order that the steps 'aH and aH1 of the part A are rendered inoperative the detachable step piece a carrying the steps is removed whereby the control table A is rendered entirely inoperative. With the table A so modified the normal rising movements of the member C1 under the action of the cam edge -O1 of the link O5 is attained by means of the ledge OA11 of the link O5 which is adapted to contact the pin C4 when the latter is in the hole CA4.

In Fig. 8 is illustrated the mechanism of Figs. l-6 adapted to control an electrical furnace in which a transformer NA1 is arranged to supply heating current to a furnace, not shown, to which the instrument of Figs. 1-6 is responsive. 'I'he instrument proper for controlling the circuit of Fig. 8, may be identical in all respects to that described in connection with Fig. 6 but the circuit connections of and apparatus associated with switches D, B0, C0 and new switch AA is somewhat different. Switch AA may be identical to switches B9 and Cu differing from switch A0 of Fig. 7 only in thatswitch AA has no center contact so that it is open circuited in its mid position. Switches Bo and Co in Fig.A 8 act as single pole switches.

In general, the manner of controlling the electrical current input. to the furnace in Fig. 8

a motor driven rheostat R, two automaticallycontrolled resistors RL and RH and manually adjustable resistors RT, RT1 and RM all in circuit with said reactor across a direct current control supply line RD-RDI.

rExcept for the sensitivity resistor RTI later described, the resistors referred to are included in a single series circuit which may he traced from DC line conductor RD to resistor RH, conductor resistor RL, conductor R133, resistor RM, reactor NAZ, conductor RDI, contact RD5, resistor R, conductor RDS, resistor conductor RD7 to the opposite line conductor RDI. Whether resistors RH and RL are in circuit and the amount of resistance R in circuit depends upon the positions of switches D, AA, E and C0 whereby the value of the current in the reactor circuit is governed. Switches D0 and AA control a reversible electric motor r for positioning contact RD of resistor R. and resistors RH and RL are cut in and out by switches E0 and CiJ respectively.

When the member E is deflected over its neutral path N as it will be deflected with a normal sistor RH from the reactor circuit. The circuit thus completed proceeds from line RD to conductor CH, switch Bo then closed, conductor CHI, resistor RL, conductor RD3, resistor RM, reactor NAZ, conductor RD4, contact RD5, resistor R, conductor RDG, resistor RT, conductor RD" and line RD1 whereby a current exists in the reactor circuit which determines a current supply to the furnace calculated to maintain the latter at a normal temperature value. The normal value of the current may be varied by manual adjustment of resistor RM.

A slight rise in temperature in the furnace which will result in deflection of member E over its path H will not change the positions of switches B0 and C0 but will tilt switch AA to its forward position in which a circuit will be closed from a. c. supply circuit conductor RC to switch D0, conductor DA, switch AA, conductor RCH, field rH of motor v', conductor RC3 and opposite line conductor RC1. Motor r will thus be energized to turn contact RD5 counterclockwise increasing the amount of resistor R in series with reactor NA2 and thereby decreasing the current in the reactor circuit and decreasing the current supplied to the furnace. The amount of movement imparted to contact RD by energization of motor r may be governed by the gearing therebetween or, as will be clear from the description following of Fig. 9, an interrupter may be inserted in the energizing circuit for motor r to govern the running time of the latter. As shown in Fig. 8 motor r will run for practically the entire cycle f with switch AA closed and switch D'J actuated as described in connection with Figs. 1 6.

With a high temperature condition such as to result in a deflection of member E over its path HI, switch AA will again be tilted to its forward position in which motor r is energized and switch C'J will remain in its forward position but switch B0 will be tilted to its back position. In the back position of switch Bo the connection between conductors CH and CHI is interrupted throwing ksistor RH into the reactor circuit to appreciably decrease the current in the latter thereby appreciably decreasing the heat supply to the furnace. It will be understood that as long as the condition remains olf normal, the contact RD5 will be moved in a direction tending to restore the condition so that the collective correction eilected by motor 1' will be a function of the length of time during which the condition is departed and is floating in the sense that the sum of the corrections added by motor r as the condition is departing, will equal the sum of the corrections subtracted by the motor as the condition is returning, only if the time of departure is equal to the time of return.

On a fall below normal of the furnace condition such that member E is deflected over path L, switch AA will be tilted in a direction to close an energizing circuit for motor .r from conductor RC, switch D0, conductor DA, switch AA, conductor RCL, to field 1L of motor 1', and line conductor RCI to turn contact RD5 clockwise and decrease the resistor R in the reactor circuit and increase the heat supply to the furnace. Switches B0 and C0 will then be in their front positions of Fig. 8 in which resistor RH is out of circuit and resistor RL is in circuit. The resistances in the reactor circuit will therefore differ from normal only by the amount removed through the operation of motor 1'. A further fall in temperature resulting in deflection of member E over path LI in which switch AA is maintained in a position to energize field rL, switch Bo is maintained in its forward position and switch C0 is actuated to its back position; will complete a shunt circuit around both resistors RL and RH. This circuit, from line RD to conductors CH, and CHI, switch C0, conductors CHL and RD, resistor RM, reactor NA, conductor RD4, contact RD5, resistor R, conductor. RD, resistor RT and conductor RD" to line RDI is the lowest resistance path provided in which the maximum current supply to the furnace is permitted to flow in the circuits above traced.

The portion of the resistor R not in the series circuits above traced is connected at its free end by conductor RD to member R'I'fi in contact with resistor RTI and the latter is connected by means of conductor RDI to line RD thus forming a circuit in parallel with the branch circuit including resistors RH, RL, RM and reactor NA. Contact RT:i of resistor RTI and contact R'I2 of resistor RT are mechanically connected and are manually adjustable together, so that the portion of each resistance in circuit at any time is proportional By varying the portion of resistors RT and RTI in circuit, the extent of reactor current change for a given movement of motor r is-,determined and by virtue of the mechanical coupling between resistors RT and R'r1 the symmetry f the circuit u preserved so that a given movement of contact RD5, in any portion of its range of movement, will result in a given reactor current change.

In Fig. 9 is shown the control instrument adapted for the control of a two motor mechanism. The only modification made in the apparatus of Figs. 1-6, to adapt that mechanism to the control circuit of Fig. 9 is the addition of an interruptor mechanism corresponding generally to the device for controlling switch D of Fig. 3 but diering from the latter in the operation timing as shown in Fig. 3A. A switch Da, which may be identical to switch D, is mounted on bracket DaI pivoted at Daz and having a pin Daii adapted to be engaged by a latch piece Da. Latch Da4 pivoted to the instrument side plate at Das is spring urged in a direction to hook overl pin Da3 to hold bracket DaI in the oi position but once in each rotation of shaft l2, a cam piece |2Da fastened thereto engages arm Da of latch Da4 permitting bracket Da1| to turn clockwise under the action of gravity into its on position.

Subsequently a wiping roller Da, fixed to Adisc l Da, the latter of which is fixed to shaft I2, engages edge Dag of bracket Da1 to turn the latter to its off position in which position it is held by latch Da4 until the latter is again released by cam IZDa. The energizing period between the release of bracket Da.l and the latching of the latter is preferably regulatable by means of the manual adjustment of disc Da with respect to cam piece I2Da. The relation of cam i2Da and disc Das is fixed for a given adjustment by the pin and hole connection comprising a pin IID fixed to cam I1, a, hole I1Dl in cam I2Da and a series of holes HD2 in disc Da. Holes I'ID2 are designated as .9, 1.1, 1.6, 2.1, 2.7 and 3.2 representing the number of seconds, in a total cycle of 3.6 seconds, during which switch Da is closed.

Switches A, B0, C and D0 of Fig. 9 are identical to the similarly identified switches of Fig. 6 the switches B0 and C0 acting as single pole switches as in Fig. 8. Switch AA of Fig. 9 is identical to switch AA of Fig. 8 and its function in Fig. 9 in connection with the interruptor provisions of switch Da and selection provisions of switch A0 is quite as well adaptable to Fig. 8 as will hereinafter appear. Switches A0 and AA are mounted together on bracket hA. Motors Ma and Mb of Fig. 8 which replace motor M Vof Fig. 6, are adapted to jointly control parts' MNa, Na, and Na1l corresponding to parts MN, N and Nl of Fig. 6. Motor Ma having reversing fields Mal and Mah is so geared to lever MNa. that it imparts a slow movement to valve Nal when energized and motor Mb having reversing elds Mbh and Mbl is so geared to lever MNa that it willr when energized, impart a rapid movement to valve Nal. The extent of movement in the opening and closing directions respectively of motor Ma is governed by limit switches Laliand Lah of a well known type. The extent of movement of motor Mb upon each energization is limited by switches Lbland Lbh. At the termination of movement of motor Mb'in either direction, the switch Lbl or Lbh. then energized, will be opened and a contact, connected with a` conductor.

MbN, will be simultaneously brought into ensagement with the other switch.

In operation, with a low condition of the furnace, whereupon member E is deflected over its path L1, the various switches will be moved to the positions indicated in Fig. 9 energizing motors Ma and Mb as follows. A circuit for motor Ma will be closed from line LC to switch D0, conductors DC switch C0, conductors CL and AAL, switch Lal, field MaL of motor Ma., armature Ma2 and opposite line LCI. Motor Ma will thus be energized for a complete cycle, terminated by the opening of interruptor switch D0 to move valve N in the opening direction. A circuit for motor Mb will be closed from line LC to switch D, conductors DC and DA, switch A0, conductor AL, switch Lbl, field Mbl, armature Mb1 and line LCI. Motor Mb will thus be energized until limit switch Lbl is actuated as a result of rotation of motor Mb which will occur before interruptor switch D is opened.

Upon a rise in the furnace condition whereby member E is deflected over its path L, switches A, AA, and` B0 will be left in the positions of Fig. 9 but switch C0 will be turned to its forward position. The energizing circuit just traced for motor Mb will again be completed but that circuit is then open at limit switch Lbl, and motor Mb is in its furthermost open position so that no further energization of motor Mb will occur when member E is deflected over its path L after an immediately preceding deflection over path L1.

The previously described energizing circuit forv field Mal having vbeen broken by the tilting of switch C0, motor Ma is energized over a circuit from line LC, to switch D0, conductor DDa, switch Da, conductor DAA, switch AA, conductor AAL, field Mal, armature Ma2 and line LC1. Motor Ma will thus be energized in the opening direction until the circuit is broken by the opening of switch Da. under the cam action previously described, the running period being less than the running period terminated by the opening of switch DD in the circuit previously traced.

From the foregoing it will be clear that motor Ma will be given a longer or shorter movement in theclosing direction as member E is deflected over paths L1 and L respectively and motor Mb will be given a movement to a fixed limit upon deflection of member E over either path L1 or L unless the motor Mb is already at said limit.

When the furnace conditions are so balanced at normal that member E is deflected over its neutral path N, switches A and AA will be moved to their neutral or mid position but no change will occur in the positions of switches B0 and C from their last mentioned positions. Switches AA and Co being open, no energizing circuits for motor Ma are completed and the latter is left in the position to which it was last adjusted. The movement of switch A0 to its mid position connects the mid point thereof, to which conductor MbN is connected, to switch blade Lbh which is then in connection with conductor MbN due to the opening of switch Lbl on the previous energization of field Mbl, and the field Mb'h. will be energized over a circuit from line LC, switch D, conductor DC, conductor DA, switch A0, conductor MbN, switch Lbh to field Mbh, armature Mb1 and line LC. Motor Mb thus energized Will rotate in the closing direction until switch Lbh is separated from conductor MbN which will occur when motor has been returned to a midposition in which switch Lbl will be permitted to reconnect to conductor AL.

Deflection oi.' member E over its paths H or H1 as a result of high furnace conditions will oppositely energize motors Ma and Mb through fields Mah and Mbh. Field Mah is under control of switches AA, B and Da in-,a manner analogous to the manner in which field Mal is controlled by switches AA, C and Da the circuits being completed to field Mah over conductors DB and AAH. Field Mbhrvr is under control of switch A over conductor AH as is field Mbl, and the restoration to neutral over conductor MbN after energization of field Mhb, is attained over switch Lbl and field Mbl ina manner analogous to the reverse movement described in connection with switch Lbh and conductor MbN.

, It will be apparent from Figs. 6 and 9 that `by replacing the motor Mb of Fig. 9 with motor M of Fig. 6 that live positions of the valve mechanism in combination with two degrees of step by step adjustment of the mechanism due to motor Ma might be obtained. 'I'he latter combination would consist in the addition of another pair of switches corresponding to switches Bo and `Co of Fig. 6 which together with switch A0 of Fig. 9l

would control motor M if the latter replaced motor Mb. The circuits for motor Ma would be unchanged.

As will be apparentto those skilled in the art,

the control apparatus shown is characterized by the relative simplicity and effectiveness of the provisions for obtaining five position control. The apparatus is characterized, moreover, by the simplicity and effectiveness with which a broad range of control is had in joint response to the value and trend of change in the controlling condition. Thus, as is made clearly apparent in the above Table No. l, when the trend is stationary, the control apparatus is adjusted into five different positions corresponding to five diiferent values of the controlling condition. When the trend is rising, the apparatus will be adjusted into a different position for each of four of the condition values, from that into which the apparatus is adjusted when the trend is stationary, and when the trend is falling, for each of four values of the condition, the adjustment will be different from that obtained for the same value when the trend is stationary or rising.

While in accordance with the provisions of the statutes, we have illustrated and described the best form of embodiment of our invention now known to us, it will be apparent to those skilled in the art that changes may be made in the form of the apparatus disclosed without departing from the spirit of our invention as set forth in the appended claims and that in some cases certain features of our invention may be used to advantage without a corresponding use of other features.

Having now described our invention, what we claim as new and desire to secure by Letters Patent, is:

1. The combination with a potentiometric control instrument comprising a. galvanometer defleeting in accordance with the variations in aV controlled quantity, a member adjusted into one or another of a definite plurality of different predetermined positions in selective accordance with the galvanometer deflection into predetermined portions of its deflection range, an element adjusted into one or another of a definite plurality of different predetermined positions in selective accordance with predetermined different magnitudes of said quantity, of control instrumentalities adjustable to five different predetermined positions, and means actuated by the adjustments of said member and element into particular ones of their different predetermined positions for adjusting said control instrumentalities to a particular one or another of said nve positions.

2. The combination in potentiometric control apparatus, of a galvanometer pointer defiecting in accordance with variations in the quantity measured, a member controlled by said galvanometer and selectively moved to one of three positions accordingly as the magnitude of the quantity is increasing, is stationary or is decreasing, an element deflecting under control of the galvanometer into different positions corresponding to dif-A ferent values of said quantity, a control motor means cooperating with said elements to operate said motor to one of three positions accordingly as the position of said element is at, below, or above a predetermined normal, means dependent upon the position of said member for nuilitying the action oi' the first mentioned means when said member is in a position corresponding to an increasing value of the quantity and said part is below its predetermined normal position and said member is in a position corresponding to a decreasing value of the quantity and said element is above its predetermined normal position,- and for actuating said motor to a fourth position when said member is in a position corresponding to an increasing value of said quantity and said element is above its predetermined normai position, and for actuating said control means to a fifth position when said member is in a position corresponding to a decreasing value of said quantity and said part is below its predetermined normal position.

3. The combination in potentiometric control apparatus, of a galvanometer pointer deflecting in accordance with variations in the quantity measured, a member controlled by said galvanometer and selectively moved to one of three positions accordingly as the magnitude of the quantity is increasing, is stationary or is decreasing, an element deflecting under control of the galvanometer into different positions corresponding to different values of said quantity, a control motor means cooperating with said elements to operate said motor to one of three positions accordingly as the position of said element is at, below, or above a predetermined normal, means dependent upon the position of said member for nullifying the action of the rst mentioned means when said member is in a position corresponding to an increasing value of the quantity and said part is below its predetermined normal position and said member is in a position corresponding to a decreasing value of the quantity4 and said element is above its predetermined normal position, and for actuating said motor to a fourth position when said member is in a position corresponding to an increasing value of said quantity and said element is above its predetermined normal position, and for actuating said control means to a fth position when said member is in a position corresponding to a decreasing value of said quantity and said part is below its predetermined normal position, and for actuating said control means to said fourth and fifth positions, respectively, when the position of said element is above or below said predetermined normal position by an amount greater than that required to actuate said motor from one to another of said three positions.

4. Control apparatus comprising in combination, a member adjusted to one or another of three positions accordingly as the trend of change in the value of a controlling condition is rising, stationary, or falling, a. second member which is adjusted into a. diiferent position for each of a plurality of condition values including a normal value, and more than one value higher, and

more than one value lower than said normal value, a control element, and means jointly controlled by the adjustment positions of said members for giving said element a different adjustment for each of said values when the trend is stationary, and, when the trend is rising, for giving said element an adjustment for each of said values, except the lowest one, which is the same as the adjustment given the element for the next lower value when the trend is stationary, and, when the trend is falling, for giving the element an adjustment for each of said values, except the highest one, which is the same as the adjustment given the element for the next higher value when the trend is stationary.

5. Control apparatus comprising in combination, a member adjusted to one or another of three positions accordingly as the trend of change in the value of a controlling condition is rising, stationary, or falling, a second member which is adjusted into a different position for each of ve different condition values, a control element,

and means jointly controlled by the adjustment positions of said members for giving said element a different adjustment for each of said values when the trend is stationary, and when the trend is rising, for giving said element an adjustment for each of said values, except the lowest one, which is the same as the adjustment given said element for the next lower value when the trend is stationary, and, when the trend is falling, for giving said element an adjustment for each ofsaid values, except the highest one, which is the same as the adjustment given said element for the next higher value when the trend is stationary.

6. In a control instrument, a member adjusted into different positions in accordance with variations in one control condition, and comprising an engaging surface, a second member adjusted into different positions yin accordance with variations in a second controlling condition, a control element having an eng-aging part and biased for movement in the direction for the engagement of said surface by said part, and a pin and slot connection between said control element and said second member, whereby the position of said element when its said partis in engagement with said engaging surface, is jointly dependent on the adjustments of both members.

'7. In a control instrument, a member adjusted about a horizontal axis into different positions in accordance with variations in one control condi- ,tion,and comprising an engaging surface, a second member adjusted angularly about a horizontal axis into different positions in accordance with variations in a second controlling condition, a control member having an engaging part and having a gravitational bias for movement in the direction for the engagement of said surface by said part, and a pin and slot connection between said control element and said second member permitting movement of said element in said direction relative to said second member, whereby the position of said element, when in engagement with said engaging surface, is jointly dependent on the adjustments of both members.

8. Control apparatus comprising inl combination, a. reversible control motor, a switch mechanism adjusted by said motor into different positions by movement ofthe motor into different positions, a plurality of control switches, an adjustable switch actuating member for operating the last mentioned switches in selective accordance withthe adjustment of said member, means responsive to variations in a control condition'A for giving said member a plurality of adjustments greater in number than the number of said control'switches including an intermediate adjustment and a plurality of adjustments at each side of, and diiierently displaced from said intermediate adjustment, and means including said switches and switch mechanism for energizing said motor for movement into different positions corresponding respectively to the diierent adjustments of said member. j

,9. Control apparatus comprising in combination, a reversible control motor, a switch mechanism adjusted by said motor into different positions by movement of the motor into different positions, a plurality of control switches, an adjustable switch actuating member for operating the last mentioned switches in 'selective accordance with the adjustment of said member; means responsive to lvariations, in a control condition for giving said member a plurality of adjustments greater in number than the number of said control switches, and means including said switches and switch mechanism for energizing said motor for movement into different positions corresponding respectively to the different adjustments of said member.

10. In control apparatus, a reversible electric control motor, a limit switch mechanism comprising a movable member adjusted into different positions by movement of the motor into different positions along the range of movement of the latter, movable contacts carried by said movable member and adjusted by the movements of the latter, movable contacts suported independently of` said member but engaged and adjusted by said member on movements of the latter into predetermined positions, stationary contacts, a plurality of switches, means for adjusting said switches intodifferent positions in accordance with variations in a controlling condition, and motor' energizing means including said switches and contacts adapted on the described adjustments to eiect movements of said motor into a number of predetermined positions exceeding the number of said switches.

11. In control apparatus, a reversible electric control motor, a limit switch mechanism comprising a movable'member adjusted into different positions by movement of the motor into a plurality of predetermined positions along the range of movement of the latter, movable contacts carried by said movable member and adjusted. by the movements of the latter, movable contacts supported independently of said member but engaged and adjusted by said member on movements of the latter into predetermined positions, stationary contacts, a plurality of switches, means for adjusting said switches into different positions in accordance with variations in a controlling condition, and motor energizing means# including said switches and contacts and adapted on the 4described adjustments to effect movements of said motor into said predetermined positions greater in number than the number of said control switches. Y

12. In a control instrument, an adjustable member having an engaging surface, means for adjusting said member into different positions in accordance with variations in one control condition,'a second adjustable member, means for adjusting the latter into different positions in accordance with variations in a second controlling condition, a controlling element having an engaging part and biased for movement in the directionfor the engagement, of said surface by said part, a pin and slot connection between said control element and said second member, whereby when both of said means are operative and said part is in engagement with said engaging surface, the position of said element is, jointly dependent on the variations in both of said conditions, and means for rendering either of the tworst mentioned means inoperative without rendering the other inoperative, whereby the position of said element, when its said part is in engagement with said surface, may be made dependent oi' variations in either one of said conditions.

13. Control apparatus comprising in combination an electrical heater, meansV responsive to the temperature therein, means controlling the current supply tosaid heater comprising a circuit network including a plurality of :lixed resistors adaptedto be selectively shuntedV by said,`

means in accordance with said temperature con,

varied by said means in accordance with said temperature condition.

14. Control apparatus for an electrical heater comprising a circuit network, including a plurality of fixed resistors and a variable resistor, and means responsive to the temperature of said heater for controlling said network including a device responsive to a departure of said temperature from a predetermined value for moving said variable resistor in a direction to oppose said departure, and a device adapted to shunt one of said resistors from said circuit network upon a further departure of said temperature from said predetermined value.

15. Control apparatus for an electrical heater comprising a circuit network including a plurality of fixed resistors and a variable resistor, means responsive to the temperature of said heater for controlling said network including an element responsive to the trend of said temperature, an element responsive to the magnitude of said temperature and means jointly controlled by said elements and actuated to a plurality of positions including ar neutral position, a high position, a higher position, a low position and a lower position corresponding to the combinative effects of the magnitude and the trend of said condition, means responsive to said high and low conditions respectively for actuating said variable resistor, and means responsive to said higher and lower conditions respectively to selectively shunt said fixed resistors.

16. Control apparatus comprising in combination, an adjustable control device, a plurality of control switches movable relative to one another, an adjustable switch actuating member for adjusting said switches into different positions relative to one another in selective accordance with the adjustment of said member, means responsive' to variations in a control condition for giving said member an intermediate adjustment and a plurality of diiferent adjustments at each side of its neutral position, and circuit connections between said switches and devices for adjusting said device into a. plurality of diilerent conditions respectively corresponding to the different adjustments of said member.

17. Control apparatus comprising in combination, an adjustable control device, a plurality of control switches movable relative to one another, an adjustable switch actuating member for adjusting said switches into different positions relative to another in selective accordance with the adjustment of said member, means responsive to variations in a control condition for giving said member an intermediate adjustment and a plurality of different adjustments at each side of its intermediate adjustment, and circuit connections between said switches and devices for adjusting said device into a neutral condition and into a plurality of different conditions at each side of its neutral condition, accordingly, as said member is given one or another of its different adjustments.

18. Control apparatus comprising in combination, a reversible electrical motor, four pairs of switch contacts adjustable into five diilerent relative positions for selectively controlling said motor in opposite directions for two-.different periods of time, a control instrumentality responsive to a condition and including means for adjusting one pair of said contacts into the closed position thereof with one extreme value of said condition and adjusting the last mentioned contacts into the o3 position with all other Values of said con- 'amasar dition, adjusting another pair of said contacts into closed position with the other extreme value of said condition and adjusting the last mentioned contacts into open position with all other values of said condition, adjusting a third pair of contacts into closed position with a value of said condition intermediate the first mentioned extreme value of said condition and the normal value of the latter, adjusting the fourth pair of contacts into closed position with a value of said condition intermediate the second mentioned extreme value of said condition and the normal Value thereof, and interruptor switch means in series with said contacts for interrupting the circuit for a period, second interruptor switch means in series with the third and fourth mentioned contacts only for closing the circuit through the latter for a period which is different from the closed period through the first and second mentioned pairs of contacts.

19. Control apparatus comprising in combination a reversible electrical motor, a circuit network including a path over which said motor is energized to rotate in one direction for a period, a second path over which said motor is energized to rotate in the opposite direction for substantially the same period, a third path over which said motor is energized to rotate in the first mentioned direction for a period shorter than the first mentioned periodband a fourth path over which said motor is energized to rotate in the second mentioned direction for a period shorter than the second mentioned period, a control instrumentality including an element deflecting in response to a condition to be controlled from a normal position thereof to an extreme position in one direction or the other and to first and second intermediate positions between said normal and extreme positions in either direction, mercury switch control means including four pairs of contacts for controlling said motor over said circuit network, relay mechanism, interposed between said element and means, for adjusting the latter into a position in which one of said pairs of contacts is closed to complete the rst mentioned path when said element is in one extreme position, adjusting another pair of said contacts into closed position to complete the second mentioned path when said element is in its opposite .extreme position, adjusting a third pair of contacts into closed position to complete the third mentioned path when said element is in the first intermediate position, adjusting a fourth pair of contacts into closed position to complete the fourth mentioned path when the said element is in the second intermediate position, and means for maintaining the mercury switch means in the adjusted position thereof corresponding to a given position of said element until readjusted by said mechanism in response to the movement of said element to another position thereof.

20. Control apparatus including a deflecting meter element, a reversible electrical motor, mercury switch control means for said motor including four pairs of contacts, a circuit network including said contacts and motor and first, second, third and fourth paths over which said motor is energized including respectively first, second, rthird and fourth pairs of contacts, pivoted means for controlling the tilting of said mercury switch means, mechanical relay means including a pivoted element adapted to cooperate;with said pivoted means, cam means giving said pivoted means and element relative retacts closed,. pivoted means for controlling the ciprocatory motion, and selective means governing the cooperation of said pivoted means and element to tilt said mercury switch means into and maintain in one of ve relative positions accordingly as said meter element is in a slightly high positionya higher position, a slightly low position, or a low position, said contacts being so arranged and disposed that one pair thereof is closed in one of five relative positions of said mercury switch means, corresponding to said higher position of said element, but is open in all other of said relative positions, a second pair thereof is closed in a second of five relative positions of said mercury switch means, corresponding to said lower position of said element but is open in all other of said relative positions, a third pair thereof is closed in a third of ve relative positions of said mercury switch means,

` corresponding to said slightly high position of said element, and a fourth pair thereof is closed in a fourth of five relative positions of said mercury switch means, corresponding to said slightly low position of said element.

21. Controlapparatus including a defiecting meter element, a reversible electrical motor, mercury switch control means for said motor including fourpairs of contacts, a circuit network including said contacts and motor and first, second, third and fourth paths over which said motor is energized, including respectively first, second, third and fourth pairs of said contacts, pivoted means for controlling the tilting of said mercury switch means, mechanical relay means including a pivoted element adapted to cooperate with said pivoted means, cam means for oscillating said element toward and away from said pivoted means and selective means for mov- .ing said element transversely of the general path imparted to it by said cam means to direct said element over one of five paths selectively dependent upon the position of said element with respect to a predetermined normal position of the latter, the engaging portions of said pivoted means and element being so configured vas to adjust said pivoted means into one of five positions depending upon the selected path of said element, said pivoted means and mercury switch means being so disposed and related that one of said pairs of contacts will be closed in one extreme position of said pivoted means, another of said pairs of contacts will be closed in the other extreme position of said pivotedemeans, and the third and fourth pairs of contacts will be closed respectively in the positions of said means intermediate the mid position and said extreme positions respectively.

22. Control apparatus including a deflecting meter element, a reversible electrical motor, mercury switch control means for said motorincluding seven pairs of contacts, a circuit network including said contacts and motor and first, second, third and fourth paths over which the first mentioned moto!` is energized including respectively first, second, third and fourth pairs of said contacts, to'rotate the first mentioned motor in one direction or the 'other respectively for a period, or is energized'to rotate in one direction or the other respectively'for a period which is shorter than thefirst mentioned period, and fifth, sixth and seventh paths over which the second mentioned motor isenergized including respectively fifth, sixth, and seventh pairs of said contacts, to rotate the second mentioned motor to one of three` positions selectively dependent upon thejpair'of'said iifth, sixth or seventh contilting of said mercury switch means, mechanical relay means including a pivoted element adapted to cooperate with said pivoted means,

cam means giving said pivoted means and ele-v ment relative reciprocatory motion, and selective means governing the cooperation of said piv-v oted means and element to tilt said mercury switch means into 'and maintain in one of ve relative positions accordingly as said motor element is in a slightly high position, a higher position, a slightly rlow position or a low position, said contacts being so arranged and disposed so that one pair of the first mentioned five thereof is closed in one of five relative positions of said mercury switches, corresponding to said higher position or said element but is open in all other of said relative positions, a second pair of the first mentioned five thereof is closed in a second of five relative positions of said mercury switch means, corresponding to said low position of said element but is open in all other of said relative positions, a third pair of the first mentioned five thereof is closed in a third of ilve relative positions of said mercury switch means corresponding to said slightly high position of said element, and a fourth pair of the first mentioned ve thereof is closed in a fourth of five relative positions of said mercury switch means, corresponding to said slightly low position of said element, the sixth/(pair thereof is closed in one of iive relative positions of said mercury switch means corresponding to a position of said element intermediate said slightly high and slightly low positions and one or the other of the fifth and seventh pairs of said contacts is closed' in all positions of said mercury switch means 'except the last mentioned position.

23. The combination in a control instrument having an element defiecting in accordance with the value of a variable condition of a plurality of pivoted mercury control switches each adjustable into a maximum of three different angular positions about a common pivot, an electrical reversible control motor adjustable into more than three different predetermined positions corresponding to an equal number of positions of said element and means interposed between said element and control switches for variably adjusting the latter into positions relative to one another for energizing said motor to assume one oi' its said positions in accordance with the corresponding position of said element.

24. The combination in a control instrument having an element deflecting in accordance with the value of a variable condition,4 of a threepositional mercury control switch and two twopositional mercury control'switches pivoted on a common -axis independently adjustable thereabout, an electrical reversible control motor having ve positions corresponding to an equal number of positions of said element and means interposed between said element and switches 'for actuating the first mentioned switch to its mid position or to one or the other of the two remaining positions accordingly as said element occuples a predetermined position or is above or below thatV position respectively, actuating one of said two positional switches to its closed position in one direction and the other of said two positional control switches to its opposite position in the opposite direction when said condition exceeds a second predetermined value and actuating the said two-positional switches to their 

